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Acta Optica Sinica, Volume. 40, Issue 1, 0111009(2020)

Progress in Optical Scanning Holography

Zhenbo Ren1、* and Y. Lam Edmund2、**
Author Affiliations
  • 1MOE Key Laboratory of Material Physics and Chemistry under Extraordinary Conditions, Shaanxi Key Laboratory of Optical Information Technology, School of Physical Science and Technology, Northwestern Polytechnical University, Xian, Shaanxi 710129, China
  • 2Department of Electrical and Electronic Engineering, Faculty of Engineering, The University of Hong Kong, Hong Kong 123456, China
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    Experimental system of optical scanning holography, where dashed box shows a typical two-pupil optical heterodyne scanning imaging system

    Fig. 1. Experimental system of optical scanning holography, where dashed box shows a typical two-pupil optical heterodyne scanning imaging system

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    Static Fresnel zone plate in OSH

    Fig. 2. Static Fresnel zone plate in OSH

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    Holograms in conventional and spiral OSHs[28]. (a) Real part of hologram in conventional OSH; (b) imaginary part of hologram in conventional OSH; (c) phase of hologram in conventional OSH; (d) real part of hologram in spiral OSH; (e) imaginary part of hologram in spiral OSH; (f) phase of hologram in spiral OSH

    Fig. 3. Holograms in conventional and spiral OSHs[28]. (a) Real part of hologram in conventional OSH; (b) imaginary part of hologram in conventional OSH; (c) phase of hologram in conventional OSH; (d) real part of hologram in spiral OSH; (e) imaginary part of hologram in spiral OSH; (f) phase of hologram in spiral OSH

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    OSH with spiral trajectory[33]. (a) Raster scanning; (b) spiral scanning; (c) configuration for lensless holographic imaging of fluorescent beads

    Fig. 4. OSH with spiral trajectory[33]. (a) Raster scanning; (b) spiral scanning; (c) configuration for lensless holographic imaging of fluorescent beads

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    Sectioning images of 3D fluorescent beads with two-layer structure reconstructed by (a)(b) conventional reconstruction method and (c)(d) inverse imaging [44]

    Fig. 5. Sectioning images of 3D fluorescent beads with two-layer structure reconstructed by (a)(b) conventional reconstruction method and (c)(d) inverse imaging [44]

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    Comparison of holographic reconstruction results of 3D fluorescent beads[53]. (a) Conventional reconstruction method; (b) extended-depth-of-field imaging; (c) map of reconstruction depth; (d) 3D representation of reconstruction depth

    Fig. 6. Comparison of holographic reconstruction results of 3D fluorescent beads[53]. (a) Conventional reconstruction method; (b) extended-depth-of-field imaging; (c) map of reconstruction depth; (d) 3D representation of reconstruction depth

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    Zhenbo Ren, Y. Lam Edmund. Progress in Optical Scanning Holography[J]. Acta Optica Sinica, 2020, 40(1): 0111009

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    Paper Information

    Category: Special Issue on Computational Optical Imaging

    Received: Sep. 29, 2019

    Accepted: Nov. 21, 2019

    Published Online: Jan. 6, 2020

    The Author Email: Ren Zhenbo (zbren@nwpu.edu.cn), Edmund Y. Lam (elam@eee.hku.hk)

    DOI:10.3788/AOS202040.0111009

    Topics

    laser devices and laser physics
    Lasers and Laser Optics
    Laser physics
    laser manufacturing
    Instrumentation, Measurement and Metrology